Cohesive energy versus lattice constant curve for fcc Aluminum

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CohesiveEnergyVsLatticeConstant_fcc_Al__TE_380539271142_002

There is a newer version of this item. See CohesiveEnergyVsLatticeConstant_fcc_Al__TE_380539271142_004

Title A single sentence description.	Cohesive energy versus lattice constant curve for fcc Aluminum
Description	This Test computes an energy vs. lattice constant curve for fcc Aluminum. The curve is computed for lattice constants ranging from 0.8a_0 to 1.5a_0, where a_0 represents the equilibrium lattice constant. The value for a_0 is obtained by querying the KIM database for the results of LatticeConstantCubicEnergy_fcc_Al when paired against the Model being used.
Species The supported atomic species.	Al
Disclaimer A statement of applicability provided by the contributor, informing users of the intended use of this KIM Item.	None

Contributor	Daniel S. Karls
Maintainer	Daniel S. Karls
Published on KIM	2018
How to Cite	Click here to download this citation in BibTeX format.
Funding	Not available

Short KIM ID The unique KIM identifier code.	TE_380539271142_002
Extended KIM ID The long form of the KIM ID including a human readable prefix (100 characters max), two underscores, and the Short KIM ID. Extended KIM IDs can only contain alpha-numeric characters (letters and digits) and underscores and must begin with a letter.	CohesiveEnergyVsLatticeConstant_fcc_Al__TE_380539271142_002
Citable Link	https://openkim.org/cite/TE_380539271142_002
KIM Item Type	Test
Driver	CohesiveEnergyVsLatticeConstant__TD_554653289799_002
Properties Properties as defined in kimspec.edn. These properties are inhereted from the Test Driver.	tag:staff@noreply.openkim.org,2014-04-15:property/cohesive-energy-relation-cubic-crystal
KIM API Version	2.0
Simulator Name The name of the simulator as defined in kimspec.edn. This Simulator Name is inhereted from the Test Driver.	LAMMPS
Programming Language(s) The programming languages used in the code and the percentage of the code written in each one.	100.00% Python

Previous Version	CohesiveEnergyVsLatticeConstant_fcc_Al__TE_380539271142_001

Models

EAM_CubicNaturalSpline__MD_853402641673_002

Model	Test Results	Link to Test Results page	Benchmark time Usertime multiplied by the Whetstone Benchmark. This number can be used (approximately) to compare the performance of different models independently of the architecture on which the test was run. Measured in Millions of Whetstone Instructions (MWI)
EAM_CubicNaturalSpline_ErcolessiAdams_1994_Al__MO_800509458712_002		view	1733

EAM_Dynamo__MD_120291908751_005

Model	Link to Test Results page	Benchmark time Usertime multiplied by the Whetstone Benchmark. This number can be used (approximately) to compare the performance of different models independently of the architecture on which the test was run. Measured in Millions of Whetstone Instructions (MWI)
EAM_Dynamo_AngeloMoodyBaskes_1995_NiAlH__MO_418978237058_005	view	1989
EAM_Dynamo_CaiYe_1996_AlCu__MO_942551040047_005	view	2150
EAM_Dynamo_ErcolessiAdams_1994_Al__MO_123629422045_005	view	1604
EAM_Dynamo_FarkasJones_1996_NbTiAl__MO_042691367780_000	view	3914
EAM_Dynamo_JacobsenNorskovPuska_1987_Al__MO_411692133366_000	view	1829
EAM_Dynamo_LandaWynblattSiegel_2000_AlPb__MO_699137396381_005	view	1412
EAM_Dynamo_LiuAdams_1998_AlMg__MO_019873715786_000	view	1733
EAM_Dynamo_LiuErcolessiAdams_2004_Al__MO_051157671505_000	view	1796
EAM_Dynamo_LiuLiuBorucki_1999_AlCu__MO_020851069572_000	view	1733
EAM_Dynamo_LiuOhotnickyAdams_1997_AlMg__MO_559870613549_000	view	2016
EAM_Dynamo_MendelevAstaRahman_2009_AlMg__MO_658278549784_005	view	4909
EAM_Dynamo_MendelevFangYe_2015_AlSm__MO_338600200739_000	view	4299
EAM_Dynamo_MendelevKramerBecker_2008_Al__MO_106969701023_005	view	3273
EAM_Dynamo_MendelevSrolovitzAckland_2005_AlFe__MO_577453891941_005	view	4524
EAM_Dynamo_Mishin_2004_NiAl__MO_101214310689_005	view	4460
EAM_Dynamo_MishinFarkasMehl_1999_Al__MO_651801486679_005	view	3529
EAM_Dynamo_MishinMehlPapaconstantopoulos_2002_NiAl__MO_109933561507_005 This Model has a disclaimer This potential was developed to accurately reproduce properties of a single phase of the Ni-Al system, namely, B2-NiAl. Properties of other phases of this system are reproduced less accurately. Application of this particular potential to simulations of pure Ni or pure Al is not recommended.	view	4524
EAM_Dynamo_PunMishin_2009_NiAl__MO_751354403791_005 This Model has a disclaimer The paper reporting on this potential (G.P. Purja Pun and Y. Mishin, "Development of an interatomic potential for the Ni-Al system," Phil. Mag. 89, 3245 (2009)) contains an error in Table 6. The generalized stacking fault energies in Ni3Al listed in this table are incorrect. The correct energies computed with the new potential are (in J/m2): APB (111) 180 CSF (111) 229 SISF (111) 21 APB (100) 20	view	4364
EAM_Dynamo_PunYamakovMishin_2013_AlCo__MO_678952612413_000	view	3818
EAM_Dynamo_PunYamakovMishin_2013_NiAlCo__MO_826591359508_000	view	5936
EAM_Dynamo_SchopfBrommerFrigan_2012_AlMnPd__MO_137572817842_000	view	2086
EAM_Dynamo_SturgeonLaird_2000_Al__MO_120808805541_005 This Model has a disclaimer This model was developed as a prototype case for the Gibbs-Duhem protocol for optimizing melting points. As such, the melting point was the primary metric for its development. We have shown that the modifications to the original Mei-Davenport potential that we used to optimize T_m did not change the quality of the potential with respect to elastic constants, density, etc., but no systematic study of other properties was performed.	view	3273
EAM_Dynamo_VailheFarkas_1997_CoAl__MO_284963179498_005	view	2503
EAM_Dynamo_WineyKubotaGupta_2010_Al__MO_149316865608_005 This Model has a disclaimer Model was fit to room temperature properties and extrapolated, classical (i.e. non-quantum) low temperature properties. The intended application is for shock compression simulations, but validation against shock pressure conditions is limited. The model appears to provide accurate results in the elastic shock regime (i.e. pressure ~ 5 to 10 GPa), as documented in the paper by Zimmerman, Winey and Gupta (Phys. Rev. B, 2011). Behavior at higher pressures and in the elastic-plastic regime is unknown.	view	2150
EAM_Dynamo_Zhakhovsky_2009_Al__MO_519613893196_000	view	3016
EAM_Dynamo_ZhouJohnsonWadley_2004_Al__MO_131650261510_005	view	1989
EAM_Dynamo_ZhouWadleyJohnson_2001_Al__MO_049243498555_000	view	3465
EAM_Dynamo_ZhouWadleyJohnson_2001NISTretabulation_Al__MO_060567868558_000	view	1989
EAM_Dynamo_ZopeMishin_2003_Al__MO_664470114311_005	view	3080
EAM_Dynamo_ZopeMishin_2003_TiAl__MO_117656786760_005	view	4267

EAM_IMD__MD_113599595631_003

Model	Link to Test Results page	Benchmark time Usertime multiplied by the Whetstone Benchmark. This number can be used (approximately) to compare the performance of different models independently of the architecture on which the test was run. Measured in Millions of Whetstone Instructions (MWI)
EAM_IMD_BrommerGaehler_2006A_AlNiCo__MO_122703700223_003	view	11422
EAM_IMD_BrommerGaehler_2006B_AlNiCo__MO_128037485276_003	view	11936
EAM_IMD_SchopfBrommerFrigan_2012_AlMnPd__MO_878712978062_003	view	9144

EAM_QuinticClampedSpline__MD_532469991695_003

Model	Test Results	Link to Test Results page	Benchmark time Usertime multiplied by the Whetstone Benchmark. This number can be used (approximately) to compare the performance of different models independently of the architecture on which the test was run. Measured in Millions of Whetstone Instructions (MWI)
EAM_QuinticClampedSpline_ErcolessiAdams_1994_Al__MO_450093727396_002		view	1123

EAM_QuinticHermiteSpline__MD_029719603993_003

Model	Test Results	Link to Test Results page	Benchmark time Usertime multiplied by the Whetstone Benchmark. This number can be used (approximately) to compare the performance of different models independently of the architecture on which the test was run. Measured in Millions of Whetstone Instructions (MWI)
EAM_QuinticHermiteSpline_ErcolessiAdams_1994_Al__MO_781138671863_002		view	1508

EMT_Asap__MD_128315414717_004

Model	Test Results	Link to Test Results page	Benchmark time Usertime multiplied by the Whetstone Benchmark. This number can be used (approximately) to compare the performance of different models independently of the architecture on which the test was run. Measured in Millions of Whetstone Instructions (MWI)
EMT_Asap_Standard_JacobsenStoltzeNorskov_1996_Al__MO_623376124862_001		view	1540
EMT_Asap_Standard_JacobsenStoltzeNorskov_1996_AlAgAuCuNiPdPt__MO_115316750986_001		view	1604

LJ__MD_414112407348_003

Model	Test Results	Link to Test Results page	Benchmark time Usertime multiplied by the Whetstone Benchmark. This number can be used (approximately) to compare the performance of different models independently of the architecture on which the test was run. Measured in Millions of Whetstone Instructions (MWI)
LJ_ElliottAkerson_2015_Universal__MO_959249795837_003 This Model has a disclaimer This model was automatically fit using Lorentz-Berthelot mixing rules. It reproduces the dimer equilibrium separation (covalent radii) and the bond dissociation energies. It has not been fitted to other physical properties and its ability to model structures other than dimers is unknown.		view	610

Morse_Shifted__MD_552566534109_002

Model	Test Results	Link to Test Results page	Benchmark time Usertime multiplied by the Whetstone Benchmark. This number can be used (approximately) to compare the performance of different models independently of the architecture on which the test was run. Measured in Millions of Whetstone Instructions (MWI)
Morse_Shifted_GirifalcoWeizer_1959HighCutoff_Al__MO_140175748626_002		view	1636
Morse_Shifted_GirifalcoWeizer_1959MedCutoff_Al__MO_279544746097_002		view	1412

Morse_Shifted__MD_552566534109_003

Model	Test Results	Link to Test Results page	Benchmark time Usertime multiplied by the Whetstone Benchmark. This number can be used (approximately) to compare the performance of different models independently of the architecture on which the test was run. Measured in Millions of Whetstone Instructions (MWI)
Morse_Shifted_GirifalcoWeizer_1959LowCutoff_Al__MO_411898953661_003		view	1989

No Driver

Model	Link to Test Results page	Benchmark time Usertime multiplied by the Whetstone Benchmark. This number can be used (approximately) to compare the performance of different models independently of the architecture on which the test was run. Measured in Millions of Whetstone Instructions (MWI)
EAM_ErcolessiAdams_1994_Al__MO_324507536345_002	view	1283
Sim_LAMMPS_ADP_ApostolMishin_2011_AlCu__SM_667696763561_000	view	4813
Sim_LAMMPS_AGNI_BotuBatraChapman_2017_Al__SM_666183636896_000	view	3594
Sim_LAMMPS_BOP_ZhouWardFoster_2016_AlCu__SM_566399258279_000	view	4203
Sim_LAMMPS_MEAM_AlmyrasSangiovanniSarakinos_2019_NAlTi__SM_871795249052_000	view	8214
Sim_LAMMPS_MEAM_JelinekGrohHorstemeyer_2012_AlSiMgCuFe__SM_656517352485_000	view	13925
Sim_LAMMPS_MEAM_PascuetFernandez_2015_Al__SM_811588957187_000	view	3626
Sim_LAMMPS_MEAM_PascuetFernandez_2015_AlU__SM_721930391003_000	view	3850
Sim_LAMMPS_SMTBQ_SallesPolitanoAmzallag_2016_Al__SM_404097633924_000	view	69624

Errors

EMT_Asap__MD_128315414717_003

Model	Error Categories	Link to Error page
EMT_Asap_Standard_JacobsenStoltzeNorskov_1996_Al__MO_623376124862_000	other	view
EMT_Asap_Standard_JacobsenStoltzeNorskov_1996_AlAgAuCuNiPdPt__MO_115316750986_000	other	view

Files

LICENSE.CDDL
Makefile
README.txt
dependencies.edn
kimprovenance.edn
kimspec.edn
pipeline.stdin.tpl
runner

Download

CohesiveEnergyVsLatticeConstant_fcc_Al__TE_380539271142_002.txz	Tar+XZ	Linux and OS X archive
CohesiveEnergyVsLatticeConstant_fcc_Al__TE_380539271142_002.zip	Zip	Windows archive

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This Test requires a Test Driver. Archives for the Test Driver CohesiveEnergyVsLatticeConstant__TD_554653289799_002 appear below.

CohesiveEnergyVsLatticeConstant__TD_554653289799_002.txz	Tar+XZ	Linux and OS X archive
CohesiveEnergyVsLatticeConstant__TD_554653289799_002.zip	Zip	Windows archive

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